JP2023175744A - Electronic apparatus - Google Patents

Abstract

To provide an electronic apparatus capable of utilizing vibration of a vibration generator.SOLUTION: An electronic apparatus 1001 comprises a casing 1010, a contact member 1020 mounted in the casing 1010, and a vibration generator 1. The vibration generator 1 is fixed on the contact member 1020 or the casing 1010. There is a clearance between a surface of the vibration generator 1 facing the casing 1010 and a surface of the casing 1010 facing the vibration generator 1.SELECTED DRAWING: Figure 1

Description

The present invention relates to electronic equipment, and particularly to electronic equipment having a vibration generator.

Some electronic devices are equipped with a vibration generator that generates vibrations.

Patent Document 1 listed below discloses a structure in which a vibration actuator is attached to a touch panel of an information terminal processing device via a vibration transmission unit that reduces the frequency of vibration and transmits vibration to the touch panel.

Japanese Patent Application Publication No. 2015-70729

By the way, in such electronic equipment, etc., it is necessary to attach the vibration generator to the electronic equipment so that the vibration force generated by the vibration generator can be transmitted to the components of the electronic equipment.

The present invention was made to solve such problems, and an object of the present invention is to provide an electronic device that can utilize the vibrations of a vibration generator.

According to an aspect of the present invention to achieve the above object, an electronic device includes a housing, a touch panel attached to the housing, and a vibration generator disposed inside the housing, the vibration generator comprises a base and a plate that can be displaced in a direction toward and away from the base, an elastic member is connected to the plate and the touch panel, and the base is fixed to a mounting part provided on the housing. The outer periphery of the plate is inside the outer periphery of the base.

According to another aspect of the invention, an electronic device includes a housing, a contact member attached to the housing, and a vibration generator disposed inside the housing, and the vibration generator includes a base and a contact member attached to the housing. , a plate that is displaceable in directions away from and near the base, the elastic member is connected to the plate and the contact member, and the base is fixed to a mounting part provided on the housing. , the flange part of the base is fixed to the mounting part, and the outer periphery of the plate is inside the flange part of the base.

Preferably the plate is biased against the contact member.

Preferably, the vibration generator includes a coil.

Preferably the coil is on the plate side with respect to the base.

Preferably, the contact member is a touch panel.

According to these inventions, it is possible to provide an electronic device that can utilize the vibrations of the vibration generator.

FIG. 1 is a perspective view showing an electronic device according to a first embodiment of the present invention. FIG. 2 is a perspective view of a vibration generator. FIG. 2 is a perspective view showing the internal structure of the vibration generator. FIG. 2 is an exploded perspective view of the vibration generator. FIG. 3 is a plan view of the vibration generator. 6 is a sectional view taken along the line A1-A1 in FIG. 5. FIG. 6 is a sectional view taken along the line A2-A2 in FIG. 5. FIG. FIG. 7 is a perspective view showing an elastic member according to a first modification. FIG. 7 is a perspective view showing an elastic member according to a second modification. FIG. 7 is a perspective view showing an elastic member according to a third modification. It is a perspective view showing the elastic member concerning the 4th modification. It is a perspective view showing the elastic member concerning the 5th modification. It is a perspective view showing the elastic member concerning the 6th modification. It is a figure showing the attachment structure of a vibration generator to electronic equipment. FIG. 3 is a diagram showing the vibration generator in a state where a current is flowing through the coil. It is a perspective view which shows the 1st modification of the attachment structure of a vibration generator. It is a sectional view showing a first modification of the mounting structure of the vibration generator. It is a top view which shows the 2nd modification of the attachment structure of a vibration generator. 19 is a sectional view taken along line CC in FIG. 18. FIG. FIG. 7 is a perspective view showing a modified example of the electronic device. FIG. 7 is a plan view of a vibration generator according to a second embodiment. 22 is a sectional view taken along the line EE in FIG. 21. FIG. FIG. 7 is a diagram showing a modified example of the second embodiment. FIG. 7 is a plan view of a vibration generator according to a third embodiment. 25 is a sectional view taken along line GG in FIG. 24. FIG. It is a sectional view of the vibration generator concerning a 4th embodiment. It is a sectional view of the vibration generator concerning a 5th embodiment. FIG. 7 is a perspective view showing a vibration generator according to a sixth embodiment. It is a figure explaining the structure of the vibration generator concerning a 6th embodiment. FIG. 7 is a perspective view showing a vibration generator according to a modified example of the sixth embodiment. It is a figure explaining the structure of the vibration generator concerning the example of a modification of a 6th embodiment.

Hereinafter, an electronic device including a vibration generator according to an embodiment of the present invention will be described.

The coordinates shown in the following figures are for indicating the attitude of the vibration generator. The X-axis direction of the coordinates is the left-right direction (the positive direction of the X-axis when viewed from the origin is the right direction), the Y-axis direction is the front-back direction (the positive direction of the Y-axis when viewed from the origin is the backward direction), and the Z-axis The direction (perpendicular to the XY plane) is sometimes referred to as the up-down direction (the direction that is positive on the Z axis when viewed from the origin is the upward direction). Further, the direction perpendicular to the Z-axis is sometimes referred to as horizontal. Note that the terms left and right, front and rear, up and down, and horizontal equality are used only to explain the structure and operation, and have nothing to do with the posture or use in which the vibration generator or electronic device is used. It's not a thing.

[First embodiment]

FIG. 1 is a perspective view showing an electronic device according to a first embodiment of the invention.

As shown in FIG. 1, the electronic device 1001 includes a housing 1010, a contact member 1020, and a vibration generator 1. The electronic device 1001 is, for example, a so-called smartphone.

Contact member 1020 is, for example, a touch panel. Contact member 1020 is attached to housing 1010.

The vibration generator 1 generates vibration force to be transmitted to the electronic device 1001. In this embodiment, the vibration generator 1 is connected or fixed to the contact member 1020 directly or via another member. Note that the vibration generator 1 is not limited to being connected or fixed to the contact member 1020 directly or via another member, but may be connected or fixed to the housing 1010 directly or via another member. good.

[Structure of vibration generator 1]

FIG. 2 is a perspective view of the vibration generator 1. FIG. 3 is a perspective view showing the internal structure of the vibration generator 1. As shown in FIG. FIG. 4 is an exploded perspective view of the vibration generator 1. FIG. 5 is a plan view of the vibration generator 1. FIG. 6 is a sectional view taken along line A1-A1 in FIG. FIG. 7 is a sectional view taken along line A2-A2 in FIG.

As shown in FIG. 2, the vibration generator 1 is formed into a thin plate shape as a whole. The vibration generator 1 has a flat shape. The vibration generator 1 is a small device having, for example, external dimensions of about several tens of millimeters in each of the left-right and front-back directions, and an outer diameter of about several millimeters in the vertical direction. The vibration generator 1 has a rough disk shape with an outer diameter of, for example, about 20 mm and a thickness of about 3 mm, excluding the portion where the hole 11 is provided.

As shown in FIG. 3, the vibration generator 1 includes a base 10, a plate 30, a coil 40, and an elastic member 51.

The base 10 is made of a magnetic material. The base 10 is made of metal, for example. The base 10 is made of iron, for example. The base 10 is formed, for example, by molding a steel plate or the like using a press or the like. Note that the base 10 may be formed by processing such as cutting.

As shown in FIG. 4, the base 10 has a flange portion 15 and a recessed portion 14 recessed below the flange portion 15. The recess 14 has, for example, a circular shape in plan view. In other words, the base 10 has a thin columnar portion (cylindrical portion having a bottom surface) that opens upward. The columnar portion is, for example, cylindrical. The upper end of the column-shaped portion is a flange portion 15 that is opened in the outer circumferential direction in a flange shape. In this embodiment, the flange portion 15 is wider than other portions in the left-right direction, and the hole portion 11 is formed in the widened portion. As shown in FIG. 5, the holes 11 are arranged on both the left and right sides of the recess 14, and can be used when attaching the vibration generator 1 to an electronic device 1001 or the like.

As shown in FIG. 6, the recess 14 has a bottom portion 14a and a side wall portion 14b. As shown in FIG. 4, a portion of the front side wall portion 14b has been removed. In other words, a portion of the side wall portion 14b is recessed as if cut out.

A terminal plate 19 extending forward from the bottom portion 14a is provided in the cutout portion of the side wall portion 14b. The terminal plate 19 is a protrusion that protrudes outward from the side wall 14b. The terminal plate 19 is provided with terminals 19a and 19b for energizing the coil 40. The terminals 19a and 19b are formed, for example, on a flexible substrate or the like, and are bonded to the terminal plate 19. Note that the terminal board 19 is not provided, and a portion of the side wall portion 14b and bottom portion 14a has been removed. A route may be provided.

In this embodiment, a depression 17 and a groove 18 are formed on the upper surface of the bottom portion 14a. The depth from the top surface of the bottom portion 14a to the depression 17 or the groove portion 18 is shallower than the vertical depth of the recess portion 14 (the distance from the top surface of the flange portion 15 to the top surface of the bottom portion 14a). The recess 17 is formed approximately at the center of the recess 14 . The recess 17 is formed in a shape that matches the shape of a convex portion 20, which will be described later. For example, the depression 17 is circular in plan view. The groove 18 is formed from approximately the center of the recess 14 to the vicinity of the terminal plate 19. The groove portion 18 extends from the recess 17 to the terminal plate 19 in the front-rear direction so that the longitudinal direction is the longitudinal direction.

As shown in FIG. 6, the base 10 is provided with a convex portion 20. As shown in FIG. The protrusion 20 is arranged at the center of the base 10. The convex portion 20 has, for example, a columnar shape. In this embodiment, the convex portion 20 has a cylindrical shape. The vertical position of the upper end of the convex portion 20 is substantially the same as the upper surface of the flange portion 15. Note that the position of the upper end portion of the convex portion 20 in the vertical direction may be above or below the upper surface of the flange portion 35a.

In this embodiment, the convex portion 20 is formed separately from the main body of the base 10, which is formed of, for example, a steel plate, and is attached to the main body of the base 10. The convex portion 20 is attached to the main body of the base 10 so as to fit into the recess 17. The protrusion 20 is attached to the depression 17 by, for example, being glued or welded. Like the main body of the base 10, the protrusion 20 is made of a magnetic material. The convex portion 20 is made of metal, for example. The convex portion 20 is made of iron, for example. The convex portion 20 functions as a core (iron core) of an electromagnet using the coil 40.

As shown in FIG. 4, the coil 40 has an annular and flat shape. The coil 40 is a thin coil whose dimension in the direction of the winding axis is smaller than its dimension in the direction perpendicular to the direction of the winding axis. The coil 40 is, for example, a coil formed by winding a conducting wire and has an annular and flat plate shape as a whole. Note that the coil 40 may be formed by slicing a wound metal foil, or may be formed by laminating sheet coils. Further, the outer shape of the coil 40 may have a circular shape or a polygonal shape such as a quadrangular shape in plan view.

The coil 40 is wound in an annular manner so as to surround the convex portion 20 . That is, the coil 40 is housed inside the recess 14 . That is, the coil 40 is arranged between the outer periphery of the convex portion 20 and the inner periphery of the side wall portion 14b. The coil 40 is formed so that the upper surface of the coil 40 is not located above the upper surface of the flange portion 15, and is attached to the base 10. The coil 40, which has been previously wound into a doughnut-shaped plate, may be attached to the base 10 by being fitted into the recess 14, or the conducting wire may be directly attached to the base 10 so as to surround the protrusion 20. The coil 40 may be formed on the base 10 by winding.

A gap is provided between the inner surface of the side wall portion 14b, which is the outer peripheral portion of the base 10, and the outer peripheral side surface 41 of the coil 40. Further, a gap is provided between the outer peripheral side surface of the convex portion 20 and the inner surface 42 of the coil 40. This ensures that the base 10 and the coil 40 are in a non-contact, insulated state.

The coil 40 is, for example, a conductive wire of φ0.15 wound around 100 to 200 turns (for example, 150 turns). The specifications of the coil 40 are not limited to these, and can be selected as appropriate depending on the size, purpose, etc. of the vibration generator 1.

An end (wound end) 43a of the outer conductive wire of the coil 40 is drawn out from the inside of the recess 14 to the outside of the base 10 through the portion where the side wall 14b is removed. Further, the end (winding end) 43b of the conductive wire inside the coil 40 passes through the lower side of the coil 40 and is drawn out to the outside of the base 10 from the portion where the side wall portion 14b is removed.

In this embodiment, the winding end portion 43b is pulled out from the inside of the coil 40 to the terminal plate 19 side through the groove portion 18. Thereby, it is possible to prevent the conducting wire reaching the winding end portion 43b from being pinched between the lower surface of the coil 40 and the upper surface of the bottom portion 14a, thereby preventing a load from being applied to the conducting wire or loss of insulation. Note that in order to ensure insulation between the coil 40 and the base 10, a cylindrical insulating member may be inserted to allow the conductor of the coil 40 to pass through.

The winding ends 43a, 43b drawn out to the outside of the base 10 through the removed side wall 14b are connected to terminals 19a, 19b, respectively, by soldering or the like. By connecting a conductive wire from the outside to the terminals 19a, 19b, it is possible to energize the coil 40 through the conductive wire. Since the terminals 19a and 19b are arranged in the shape of a terminal board 19, conductive wires from the outside can be easily connected to the terminals 19a and 19b.

In this embodiment, the plate 30 has a circular plate shape parallel to the horizontal plane. Plate 30 is made of magnetic material. The plate 30 is made of metal, for example. The plate 30 is made of iron, for example. The plate 30 is formed, for example, by molding a steel plate or the like using a press or the like. Note that the plate 30 may be formed by processing such as cutting.

The plate 30 is arranged above the base 10 so as to face the base 10. As shown in FIG. 5, the plate 30 has an outer diameter that is approximately the same as the outer diameter of the peripheral edge of the flange 15 excluding the portion where the hole 11 is provided. The plate 30 is formed to cover the flange portion 15 except for the portion where the hole portion 11 is provided. As shown in FIG. 7, the lower surface of the portion near the outer peripheral portion of the plate 30 faces the upper surface of the flange portion 15. In other words, the flange portion 15 is provided at a portion of the base 10 outside the outer peripheral portion of the coil 40 and faces the surface of the plate 30.

As shown in FIG. 7, the plates 30 are arranged with a slight interval from the base 10 so as to form a magnetic circuit. An elastic member 51 is arranged between the plate 30 and the base 10. Due to the arrangement of the elastic member 51, a certain distance is provided between the plate 30 and the base 10 when the coil 40 is not energized. That is, the plate 30 is located higher than the flange portion 15 of the base 10 by the thickness of the elastic member 51.

The elastic member 51 is, for example, a resin member having restoring force, and is deformable. The elastic member 51 supports the plate 30 with respect to the base 10. The elastic member 51 is provided between the plate 30 and the base 10. In this embodiment, the elastic member 51 is arranged to be sandwiched between the flange portion 15 and the plate 30. That is, the elastic member 51 is arranged between the outer circumference of the base 10 located outside the coil 40 and the outer circumference of the plate 30 located outside the coil 40.

The elastic member 51 is bonded and fixed to the flange portion 15 using an adhesive, for example. Note that the method of arranging the elastic member 51 is not limited to adhesion. Further, the elastic member 51 may be fixed to the plate 30 or may be fixed to each of the flange portion 15 and the plate 30 by adhesion or the like. Moreover, the elastic member 51 does not need to be fixed to either the flange portion 15 or the plate 30.

As the elastic member 51, four members (elastic members 51a, 51b, 51c, and 51d; hereinafter, each of these may be referred to as the elastic member 51) are provided. A plurality of four elastic members 51 are arranged side by side in the circumferential direction. The four elastic members are arranged at predetermined intervals in the circumferential direction. That is, as shown in FIG. 5, in this embodiment, an elastic member 51a is arranged at the rear left side of the convex portion 20. As shown in FIG. An elastic member 51b is arranged on the right rear side of the convex portion 20. An elastic member 51c is arranged on the right front side of the convex portion 20. An elastic member 51d is arranged on the left front side of the convex portion 20. When focusing on a certain elastic member 51, circumferentially adjacent elastic members 51 are roughly arranged at positions rotated by 90 degrees around the convex portion 20.

The four elastic members 51 are arranged at positions apart from the elastic members 51 adjacent to each other in the circumferential direction. That is, when viewing the vibration generator 1 from the side, there is a portion between the plate 30 and the base 10 where the elastic member 51 is not present.

The elastic members 51 are arranged as a space S between the plate 30 and the base 10, a space S between two adjacent elastic members among the four elastic members 51 in the circumferential direction, and a space S inside the base 10. It is deformable toward the recess 14 of. Therefore, the space S accommodates a part of the deformed elastic member 51, and by providing such a space S, the elastic member 51 can be deformed toward the recess 14.

Note that the number of elastic members 51 is not limited to four, and may be two or three. Moreover, five or more may be provided. Further, as described later, the elastic member 51 may be annular. The elastic member 51 is not limited to being placed between the flange portion 15 and the plate 30, but may be placed between the top surface of the coil 40 and the plate 30, or between the top surface of the convex portion 20 and the plate 30. may have been done.

In this embodiment, plate 30 and base 10 constitute a magnetic circuit. The plate 30 is close to the flange portion 15 at a predetermined distance in the outer peripheral portion, and is close to the convex portion 20 at a predetermined distance in the central portion. Therefore, the plate 30 and the base 10 including the convex portion 20 constitute a magnetic circuit. Since the plate 30 and the base 10 are separated by the thickness of the elastic member 51, a magnetic gap corresponding to the thickness is provided in the magnetic circuit. The smaller the magnetic gap, the better in terms of increasing the amplitude of the plate 30 (in terms of increasing the magnetic efficiency of the magnetic circuit).

The vibration generator 1 is driven by repeating a state in which a current flows through the coil 40 and a state in which a current does not flow in the coil 40. That is, by repeatedly magnetizing and demagnetizing the electromagnet composed of the coil 40 and the base 10, the vibration generator 1 can generate vibrations.

When current flows through the coil 40, the base 10 is excited. As a result, the upper part of the base 10 and the flange part 15 become magnetic pole parts, and the plate 30 forming the magnetic circuit is also magnetized. A relatively strong magnetic attraction force is generated between the upper part of the base 10 and the center part of the plate 30 and between the flange part 15 and the outer peripheral part of the plate 30, and the plate 30 is attracted to the base 10. . As a result, the plate 30 is displaced downward with respect to the base 10 while compressing the elastic member 51, and the distance between the plate 30 and the base 10 becomes smaller. When the elastic member 51 is compressed from a state where no current flows through the coil 40, it generates a restoring force and urges the plate 30 in a direction away from the base 10. Therefore, the maximum amount of displacement of the plate 30 reaches a position where the magnetic attraction force and the restoring force of the elastic member 51 are balanced. Here, in this embodiment, the upper part of the base 10 becomes the convex part 20. Note that the upper part of the base 10 is not limited to the convex part 20, and may be a part located closer to the plate 30 than the bottom part 14a of the base 10.

When the state in which current is flowing through the coil 40 changes to the state in which no current flows in the coil 40, the magnetization disappears, so the magnetic attraction force disappears. Then, the restoring force of the elastic member 51, which is compressed as the plate 30 is displaced with respect to the base 10, acts on the plate 30, so that the plate 30 is displaced upward with respect to the base 10. This increases the distance between the plate 30 and the base 10.

By repeating a state in which a current flows through the coil 40 and a state in which a current does not flow through the coil 40, the plate 30 is repeatedly displaced in the vertical direction with respect to the base 10. That is, the plate 30 is displaced in the direction toward and away from the base 10. Thereby, the vibration generator 1 can generate vibration force. Here, the direction of distance includes, for example, the direction in which the plate 30 vibrates with respect to the base 10, and the thickness direction of the plate 30 and the base 10.

In this embodiment, the outer peripheral portion of the plate 30 faces the flange portion 15 of the base 10. Therefore, in the outer portion of the coil 40, the magnetic flux passing through the magnetic circuit is less likely to leak (magnetic resistance is lowered), and a strong magnetic attraction force is generated. Therefore, the efficiency of the vibration generator 1 can be improved. Further, the plate 30 serving as the vibration surface can be enlarged by the size of the flange portion 15. Therefore, vibrations can be efficiently transmitted to the electronic device 1001 and the like.

An elastic member 51 is arranged to be sandwiched between the plate 30 and the base 10. Therefore, even when current is flowing through the coil 40, the plate 30 and the base 10 do not come into contact with each other. Therefore, when the vibration generator 1 is driven, it is possible to prevent the occurrence of abnormal noise due to contact between the plate 30 and the base 10.

When the vibration generator 1 is viewed from the side, there is a portion between the plate 30 and the flange portion 15 where the elastic member 51 is not disposed. Therefore, when the plate 30 is displaced downward with respect to the base 10 and the elastic member 51 is compressed, the elastic member 51 can be deformed so as to expand not only in the radial direction but also in the circumferential direction. Further, by changing the dimensions such as the thickness and width of the elastic member 51, the restoring force (also referred to as elastic force) necessary for the vibration generator 1 can be obtained. Therefore, the amount of displacement of the plate 30 relative to the strength of the magnetic attraction force can be increased. Further, the space in which the coil 40 is provided and the outside of the vibration generator 1 communicate with each other through a portion between the plate 30 and the flange portion 15 where the elastic member 51 is not provided. Therefore, the heat generated by the coil 40 can be effectively radiated.

In addition, as shown by the two-dot chain line in FIGS. 3 and 4, a weight 30w may be arranged on the upper surface of the plate 30 of the vibration generator 1. When the weight 30w is disposed on the plate 30, the plate 30 is displaced together with the weight 30w, so that a stronger vibration force can be generated.

[Description of modification regarding elastic member]

The elastic member used in the vibration generator is not limited to the elastic member 51 described above, and various forms can be used. That is, the form of the elastic member may be appropriately selected depending on various factors such as the size of the vibration generator, the magnitude of the magnetic attraction force generated using the coil, and the magnitude of the necessary vibration force. .

Further, the material of the elastic member may be appropriately selected depending on the factors mentioned above. As the elastic member, rubber, synthetic resin, gel-like members, and resin members such as sponges having various types of bubbles can be used. Further, as the elastic member, a metal member such as a metal plate spring or a coil spring can be used. These are just examples, and various elastic members that are deformable and capable of supporting the plate 30 with respect to the base 10 can be used.

A material containing a magnetic material may be used as the elastic member. Thereby, the elastic member may be used as a member constituting a magnetic circuit together with the base and the plate. Thereby, the occurrence of magnetic flux leakage in the magnetic circuit can be suppressed (reduced magnetic resistance), and the efficiency of the vibration generator 1 can be improved.

For example, the elastic member may have the following form.

FIG. 8 is a perspective view showing an elastic member according to a first modification.

In FIG. 8, an annular elastic member 50A is shown in the upper part. At the bottom, four elastic members 51A (51Aa, 51Ab, 51Ac, 51Ad) each having a shape that constitutes a part of an annular elastic member 50A are shown. The four elastic members 51A may be arranged at predetermined intervals in the circumferential direction, similarly to the elastic member 51 described above. The elastic members 50A and 51A are sheet-like resin members having restoring force.

A space S that can accommodate a part of the elastic member 50A is provided inside the annular elastic member 50A.

FIG. 9 is a perspective view showing an elastic member according to a second modification.

In FIG. 9, an annular elastic member 50B is shown in the upper part. At the bottom, four elastic members 51B (51Ba, 51Bb, 51Bc, 51Bd) each having a shape that constitutes a part of an annular elastic member 50B are shown. The four elastic members 51B may be arranged at predetermined intervals in the circumferential direction, similarly to the elastic member 51 described above. The elastic members 50B and 51B are resin members having a circular cross section and having restoring force.

Inside the annularly configured elastic member 50B and the annularly arranged elastic member 51B, a space S that can accommodate a portion of the elastic members 50B and 51B is provided. Moreover, a space S is provided between two adjacent elastic members 51B among the four elastic members 51B.

FIG. 10 is a perspective view showing an elastic member according to a third modification.

In FIG. 10, two elastic members 50C (50Ca, 50Cb) each having a slightly shorter semicircular arc shape are shown in the upper row. At the bottom, four elastic members 51C (51Ca, 51Cb, 51Cc, 51Cd) each having a shape that constitutes a part of an annular elastic member are shown. The four elastic members 51C may be arranged at predetermined intervals in the circumferential direction, similarly to the elastic member 51 described above. The elastic members 50C and 51C are resin members having a cylindrical pipe shape and having restoring force. By forming the plate 30 into a cylindrical shape, the amount of displacement of the plate 30 relative to the base 10 can be increased compared to the elastic members 50B and 51B.

A space S capable of accommodating a part of the elastic members 50C, 51C is provided inside the annularly configured elastic members 50C, 51C. Further, a space S is provided between the two elastic members 50C and between two adjacent elastic members 51C among the four elastic members 51C.

FIG. 11 is a perspective view showing an elastic member according to a fourth modification.

In FIG. 11, four elastic members 51D (51Da, 51Db, 51Dc, 51Dd) are shown. The four elastic members 51D may be arranged at predetermined intervals in the circumferential direction, similarly to the elastic member 51 described above. Each of the elastic members 51D is a resin member having a spherical restoring force.

A space S capable of accommodating a portion of the elastic members 51D is provided inside the four elastic members 51D arranged in an annular manner. Moreover, a space S is provided between two adjacent elastic members 51D among the four elastic members 51D.

FIG. 12 is a perspective view showing an elastic member according to a fifth modification.

In FIG. 12, an annular elastic member 50E is shown in the upper part. At the bottom, four elastic members 51E (51Ea, 51Eb, 51Ec, 51Ed) each having a shape that constitutes a part of an annular elastic member 50E are shown. The four elastic members 51E may be arranged at predetermined intervals in the circumferential direction, similarly to the elastic member 51 described above. The elastic members 50E and 51E are resin members having a sheet-like restoring force. The surfaces of the elastic members 50E and 51E have irregularities. Specifically, a large number of small protrusions 55E are provided on the surfaces of the elastic members 50E and 51E. Since such projections 55E and the like are provided and there are irregularities, the manner in which the elastic members 50E and 51E deform when they are compressed changes from that in the case where there are no irregularities. Therefore, the vibration generated by the vibration generator 1 can be changed.

Inside the annularly configured elastic member 50E and the annularly arranged elastic member 51E, a space S that can accommodate a portion of the elastic members 50E, 51E is provided. Moreover, a space S is provided between two adjacent elastic members 51E among the four elastic members 51E.

FIG. 13 is a perspective view showing an elastic member according to a sixth modification.

In FIG. 13, an annular elastic member 50F is shown in the upper part. The elastic member 50F is a resin member having restoring force. The elastic member 50F has a sheet-shaped annular portion 55F having an annular configuration and a plurality of protruding portions 56F that protrude upward from the annular portion 55F. Each of the protrusions 56F has a rib shape extending in the radial direction of the elastic member 50F.

A space S capable of accommodating a portion of the elastic member 50F is provided inside the annularly configured elastic member 50F. Further, a space S is provided between two adjacent protrusions 56F among the plurality of protrusions 56F.

The elastic member 50F is used, for example, with the upper part of the protrusion 56F in contact with the plate 30. When the plate 30 is displaced downward, each protrusion 56F is compressed in the vertical direction. Since the protrusions 56F are spaced apart in the circumferential direction and there is a space in which the protrusions 56F can deform in the circumferential direction, each protrusion 56F is easily compressed in the vertical direction. Therefore, while utilizing the integrally formed elastic member 50F, it is possible to increase the amount of displacement of the plate 30 with respect to the strength of the magnetic attraction force, as in the case of using a plurality of elastic members, and the coil 40 can dissipate the heat generated.

Note that whether to use an annular elastic member or to arrange a plurality of elastic members at intervals in the circumferential direction may be appropriately selected depending on the application of the vibration generator 1 and the like. As described above, when a plurality of elastic members are arranged at intervals in the circumferential direction, the amount of displacement of the plate 30 relative to the strength of the magnetic attraction force can be increased, and the heat generated by the coil 40 can be increased. can dissipate heat. On the other hand, when using an annular elastic member, it is possible to eliminate the gap between the plate 30 and the flange portion 15 on the inside and outside of the elastic member. Therefore, it is possible to prevent a problem such as foreign matter from entering the inner region of the elastic member and inhibiting the displacement of the plate 30 from occurring.

[Description of the mounting structure of the vibration generator 1]

FIG. 14 is a diagram showing an attachment structure of the vibration generator 1 to the electronic device 1001.

In FIG. 14, detailed structures are shown in a simplified manner for explanation. In FIG. 14, a state in which no current flows through the coil 40 is shown.

In the electronic device 1001, a force sensor (an example of a third elastic member) 1040 is arranged between the contact member 1020 and the housing 1010. That is, the contact member 1020 is fixed to the housing 1010 via the force sensor 1040. Force sensor 1040 detects a force that presses contact member 1020 against housing 1010 when that force is applied to contact member 1020 . The force sensor 1040 is made of an elastic member having elasticity. Note that instead of or together with the force sensor 1040, an elastic member such as a plate spring, a coil spring, rubber, or synthetic resin may be arranged between the contact member 1020 and the housing 1010.

The vibration generator 1 is fixed to the contact member 1020 with the upper surface of the plate 30 facing the lower surface of the contact member 1020. For example, the base 10 is inserted from the bottom of the flange 15 upwardly through the hole 11 and the spacer 1091 with the spacer 1091 sandwiched between the upper surface of the flange 15 and the contact member 1020. It is fixed to the contact member 1020 by a screw 1090.

A gap is provided between the lower surface of the base 10 of the vibration generator 1 facing the casing 1010 and the upper surface of the bottom surface of the casing 1010 facing the vibration generator 1.

The plate 30 is capable of contacting and separating from the contact member 1020 in a direction toward and away from the base 10, that is, in an up-down direction. In this embodiment, the upper surface of plate 30 is in contact with the lower surface of contact member 1020 when no current is flowing through coil 40. When the plate 30 is in contact with the contact member 1020 in this manner, the elastic member 51 is contracted more than in its natural state (a state in which no force is applied to move the plate 30 closer to or closer to the base 10). In other words, the elastic member 51 that supports the plate 30 in contact with the contact member 1020 is deformed. That is, the vibration generator 1 is fixed to the contact member 1020 in a state where the plate 30 is slightly pressed against the base 10 by contacting the contact member 1020. With the vibration generator 1 fixed to the contact member 1020 and the plate 30 in contact with the contact member 1020, the elastic member 51 moves the plate 30 toward the contact member 1020 in the direction of moving away from and away from the base 10. energized, the plate 30 exerts an effect on the contact member 1020.

FIG. 15 is a diagram showing the vibration generator 1 in a state where a current is flowing through the coil 40.

When current flows through the coil 40, the plate 30 is displaced and approaches the base 10. At this time, the position of the base 10 does not change. That is, at this time, the plate 30 becomes separated (separated) from the contact member 1020 as shown in FIG. 15 .

Thereafter, when the current flowing through the coil 40 is stopped, the magnetic attraction force disappears. Then, the plate 30 is urged upward by the restoring force of the elastic member 51, and the plate 30 is displaced toward the contact member 1020. When the plate 30 is displaced until it contacts the contact member 1020, the plate 30 stops in contact with the contact member 1020 and returns to the state shown in FIG. 14.

In this way, by repeatedly supplying and stopping the current to the coil 40, the state shown in FIG. 14 and the state shown in FIG. 15 are repeatedly generated. When the plate 30 repeats reciprocating displacement, vibration is generated due to the reaction that the contact member 1020 exerts on the plate 30, and the vibration is transmitted to the contact member 1020. Since the contact member 1020 is connected to the housing 1010 via the force sensor 1040, which is an elastic member, the contact member 1020 is allowed to be slightly displaced with respect to the housing 1010. By transmitting the vibration to the housing 1010, the user using the electronic device 1001 can feel the vibration.

Note that when the current flowing through the coil 40 is stopped and the plate 30 contacts the contact member 1020, the plate 30 can be forcefully applied to the contact member 1020. Since an impact can be generated on the contact member 1020, the user can feel a relatively unique sensation such as a click sensation.

Note that the mounting structure of the vibration generator 1 is not limited to this. Furthermore, the vibration generator 1 can be used in various electronic devices other than the electronic device 1001.

For example, the vibration generator 1 may be attached not to the contact member side of the electronic device but to the housing side.

FIG. 16 is a perspective view showing a first modification of the mounting structure of the vibration generator 1. As shown in FIG. FIG. 17 is a sectional view showing a first modification of the mounting structure of the vibration generator 1. As shown in FIG.

As shown in FIGS. 16 and 17, the electronic device 1201 is, for example, a so-called smartphone, and includes a contact member 1020, a housing 1210, a force sensor 1040, and a vibration generator 1. The electronic device 1201 differs from the electronic device 1001 described above in that the vibration generator 1 is attached to the housing 1210 side instead of the contact member 1020 side.

As shown in FIG. 17, a mounting portion 1212 having a recess 1214 in the center is formed inside the housing 1010 to which the vibration generator 1 is mounted. The mounting portion 1212 is raised above the recess 1214 so as to support the flange portion 15 of the vibration generator 1. The vibration generator 1 is arranged such that the part of the flange part 15 where the hole part 11 is provided rests on the mounting part 1212, and the screw 1090 is attached so as to pass through the hole part 11 from above. Then, it is attached to the attachment part 1212.

In this modification, the dimension from the upper surface of the attachment part 1212 to the upper surface of the recess 1214 is slightly larger than the dimension from the lower surface of the flange part 15 of the vibration generator 1 to the lower surface of the recess 14. Therefore, there is a gap between the surface of the vibration generator 1 facing the casing 1210 (here, the lower surface of the recess 14) and the surface of the casing 1210 facing the vibration generator 1 (here, the upper surface of the recess 1214). , a gap is provided.

Plate 30 of vibration generator 1 is sandwiched between contact members 1020 with elastic member 1205 (second elastic member) in between. That is, an elastic member 1205 is provided between the plate 30 and the contact member 1020. Further, the elastic member 1205 is connected or fixed to the plate 30 and the contact member 1020 directly or via another member such as an adhesive. The elastic member 1205 is a member having cushioning properties. The elastic member 1205 is, for example, a resin member such as rubber or synthetic resin. Since the elastic member 1205 is provided, the vibration generated in the vibration generator 1 is somewhat relaxed by the elastic member 1205 and is also transmitted to the contact member 1020. Furthermore, when assembling the housing 1210, the force sensor 1040, and the contact member 1020, the dimensional tolerance between the housing 1210 and the contact member 1020 will be relatively large, and the elastic member 1205 can accommodate this tolerance. However, a force associated with the displacement of the plate 30 can be applied to the contact member 1020.

If necessary, the plate 30 may be connected or fixed to the contact member 1020 directly or via another member such as an adhesive, without providing the elastic member 1205.

FIG. 18 is a plan view showing a second modification of the vibration generator mounting structure. FIG. 19 is a sectional view taken along line CC in FIG. 18.

As shown in FIGS. 18 and 19, the electronic device 1601 is, for example, a so-called tablet computer, and includes a contact member 1620, a housing 1610, an elastic member 1640, and a vibration generator 1. . Contact member 1620 is a touch panel. The elastic member 1640 is, for example, an elastic member such as rubber or synthetic resin, and is arranged between the contact member 1620 and the housing 1610. For example, the elastic member 1640 is arranged to surround the outer periphery of the contact member 1620.

As shown in FIG. 18, in the electronic device 1601, the vibration generator 1 is fixed to the outer periphery of the contact member 1620. That is, the vibration generator 1 is connected to the contact member 1620 such that the plate 30 contacts a part of the outer circumference of the contact member 1620. As shown in FIG. 19, a gap is provided between the surface of the base 10 of the vibration generator 1 and the inner surface of the housing 1620. In FIG. 19, illustration of the internal structure of the vibration generator 1 is omitted.

In this way, even if the vibration generator 1 is fixed to the outer circumference of the contact member 1620, the vibration generated by the vibration generator 1 can be transmitted to the contact member 1620, and the vibration generator 1 can be transmitted to the contact member 1620. can be used.

FIG. 20 is a perspective view showing a modified example of the electronic device.

As shown in FIG. 20, electronic device 1401 is, for example, a steering wheel of an automobile. The electronic device 1401 has a contact member 1420 on each of three spoke portions 1407 that connect the hub 1405 and the handle 1403. Each contact member 1420 is, for example, an operation input unit including a plurality of operation switches for selecting and adjusting various functions of the automobile. The vibration generator 1 is attached to the back of each contact member 1420. By using the vibration generator 1, when the operation switch of each contact member 1420 is operated, it is possible to generate a corresponding vibration and provide the user with feedback regarding the operation.

As described above, according to the first embodiment, the vibration generator 1 has a thin structure including the base 10, the coil 40, the plate 30, and the elastic member 51. Therefore, the vibration generator 1 having a relatively large vibration surface can be downsized. In the vibration generator 1, since the base 10 and the plate 30 constitute a magnetic circuit, large vibrations can be generated efficiently. The base 10 is provided with a flange portion 15, and the plate 30 is provided to face the flange portion 15, so that magnetic flux is unlikely to leak between the flange portion 15, which serves as a magnetic pole portion, and the plate 30 (magnetic (resistance can be lowered) and larger vibrations can be generated.

A plurality of elastic members 51 having equal vertical dimensions (thickness) are arranged between the plate 30 and the base 10. Therefore, the plate 30 can be displaced while maintaining its horizontal position.

[Second embodiment]

The basic configuration of the vibration generator in the second embodiment is the same as that in the first embodiment, so the description here will not be repeated. Components that are substantially similar in shape or function to those described in the first embodiment may be designated by the same reference numerals, and a description thereof may be omitted. The second embodiment differs from the first embodiment in the manner in which the elastic members are arranged, the structure of the base, and the like.

FIG. 21 is a plan view of the vibration generator 101 according to the second embodiment. FIG. 22 is a cross-sectional view taken along the line EE in FIG. 21.

In FIG. 21, illustration of the plate 30 is omitted in order to explain the internal structure of the vibration generator 101. That is, components that are hidden behind the plate 30 in the original plan view of the vibration generator 101 are also shown by solid lines in FIG.

As shown in FIGS. 21 and 22, the vibration generator 101 includes a base 110, a plate 30, a coil 40, and elastic members 151 (151a, 151b, 151c, 151d, 151m).

In the second embodiment, a center protrusion 120 and an outer protrusion 125 are attached to the base 110. The center protrusion 120 is arranged in the recess 17 at the center of the recess 14 of the base 110, similar to the protrusion 20 of the first embodiment. The outer convex portion 125 is an annular member. The outer convex portion 125 is formed and arranged outside the outer periphery of the coil 40 so as to surround the outer periphery of the coil 40 . An annular recess 117b to which the outer protrusion 125 is fixed is formed in the bottom 14a of the recess 14 of the base 110. The center convex portion 120 and the outer convex portion 125 are made of a magnetic material, similarly to the convex portion 20. For example, the center convex portion 120 and the outer convex portion 125 are made of iron. As a current flows through the coil 40, the base 110 is excited, and the upper part of the center convex part 120 and the upper part of the outer convex part 125 each become a magnetic pole part.

The center convex portion 120 and the outer convex portion 125 are formed such that their respective upper surfaces are at the same height as the upper surface of the base 110. The plate 30 is arranged such that the outer peripheral portion of the plate 30 faces the upper surface of the outer convex portion 125. Note that the base 110 is not provided with the wide flange portion 15 arranged so as to surround the outer periphery of the recess 14 as in the first embodiment, but instead is provided with the recess 14 in which the hole 11 is provided. Only the left and right sides of the flange-like part are widened.

A depression 120a is formed in the center of the upper surface of the center convex portion 120, in which an elastic member 151m (hereinafter sometimes referred to as center elastic member 151m) is disposed. Further, the outer convex portion 125 is formed with four depressions 126 in which elastic members 151a, 151b, 151d, and 151d (hereinafter, these may be collectively referred to as outer elastic members 151) are arranged. In the second embodiment, the outer elastic members 151 are arranged at approximately equal intervals in the circumferential direction, similar to the elastic members 51 in the first embodiment. Although the depths of the depressions 120a and 126 are, for example, uniform, the depth is not limited to this, and the depth of the depression 120a and the depth of the depression 126 may be different.

In the base 110, a coil arrangement part 116 that is slightly raised upward is provided between the depression 17 in which the center protrusion 120 is arranged and the depression 117b in which the outer protrusion 125 is arranged. A coil 40 is arranged above the coil arrangement section 116. Thereby, it is possible to configure the vibration generator 1 having a vibration surface of a constant size while reducing the volume of the coil 40 as necessary. Further, in the magnetic circuit constituted by the base 110 and the plate 30, saturation of the magnetic flux at the bottom portion 14a can be prevented from occurring. Further, a coil arrangement portion 116 may be provided in order to adjust the upper surface of the coil 40 and the upper surface of the center convex portion 120 to the same height.

An insulating film (resin film) 145 is arranged on the upper surface of the coil 40. Furthermore, an insulating film (resin film) 146 is arranged on the lower surface of the coil 40 between it and the coil arrangement section 116. The insulating films (resin films) 145 and 146 are, for example, insulating resin members. Thereby, insulation between the coil 40 and the base 110 and between the coil 40 and the plate 30 can be ensured.

In the second embodiment, the base 110 has a center protrusion 120 and an outer protrusion 125, and the outer peripheral part of the plate 30 is arranged to face the upper surface of the outer protrusion 125. . Therefore, a magnetic circuit is constituted by the plate 30, the center convex portion 120, the outer convex portion 125, and the bottom portion 14a of the base 110. Therefore, the vibration generator 101 can function similarly to the first embodiment described above. The vibration generator 101 in the second embodiment can be used in various electronic devices in the same way as described in the first embodiment.

Since a relatively wide outer convex portion 125 can be used, the diameter of the plate 30 can be increased accordingly, and the efficiency of the vibration generator 101 can be improved while expanding the vibration surface. can.

Furthermore, since the depressions 120a and 126 are formed in the center protrusion 120 and the outer protrusion 125, the distance between the plate 30 and the upper surface of the base 110 can be reduced, and the height of the elastic member 151 in the vertical direction can be reduced. It can be secured for a long time. When the plate 30 is displaced toward the base 110 to compress the elastic member 151, as the amount of displacement of the plate 30 increases, the force generated by the elastic member 151 to resist it increases. The degree becomes smaller as the vertical length of the elastic member 151 in the natural state is longer. Therefore, when a current flows through the coil 40, the magnitude of the magnetic attraction force acting between the plate 30 and the base 110 can be increased, and the elastic member 151 can be easily compressed.

As the plate 30 is displaced downward with respect to the base 110, the center elastic member 151m is deformed and compressed while expanding in the radial direction. Therefore, since the plate 30 is stably supported at the center of the plate 30, when the plate 30 is repeatedly displaced in the vertical direction, the plate 30 is difficult to be displaced in the horizontal direction. Therefore, vibration can be generated stably.

FIG. 23 is a diagram showing a modified example of the second embodiment.

As shown in FIG. 23, the vibration generator 201 includes a base 210, a plate 30, a coil 40, and elastic members 151b and 151d. The vibration generator 201 is different from the vibration generator 1 according to the second embodiment described above mainly in that it does not have the center elastic member 151m and that it does not have the coil arrangement part 116. There is a difference between Note that in FIG. 23, a cross section passing through elastic members 151b and 151d among the plurality of elastic members 151 is shown.

The base 210 has a protrusion 20, an outer protrusion 125, and a spacer 228. The protrusion 20 is arranged in the recess 17 of the bottom 14a of the recess 14. The outer convex portion 125 is arranged in an annular depression 117b formed in the bottom portion 14a. The spacer 228 is disposed on the bottom 14a between the protrusion 20 and the outer protrusion 125. The spacer 228 has a ring shape with an outer diameter slightly smaller than the inner diameter of the outer protrusion 125 and an inner diameter slightly larger than the outer diameter of the protrusion 20 . The spacer 228, like the convex portion 20 and the outer convex portion 125, is made of a magnetic material. For example, spacer 228 is made of iron. By forming the spacer 228 with a magnetic material, the magnetic efficiency of the magnetic circuit is improved, and the amplitude of the vibration generated by the vibration generator 1 can be increased. Coil 40 and insulating films 145, 146 are placed on spacer 228. Note that the spacer 228 may be made of a non-magnetic material such as resin. An insulating member may be used as the spacer 228 to ensure insulation of the coil 40 more reliably.

In the vibration generator 201 as well, a magnetic circuit is configured by the plate 30, the convex portion 20 of the base 210, the outer convex portion 125, and the bottom portion 14a. Therefore, the vibration generator 201 can function similarly to the second embodiment. Although the vibration generator 201 does not have the center elastic member 151m, the provision of other elastic members 151 allows the vibration generator 201 to function. A center elastic member 151m may be provided to enable more stable displacement of the plate 30 in the vertical direction.

[Third embodiment]

FIG. 24 is a plan view of a vibration generator 401 according to the third embodiment. FIG. 25 is a sectional view taken along line GG in FIG. 24.

As shown in FIGS. 24 and 25, the vibration generator 401 includes a base 410, a plate 430, a coil 40, and elastic members 151 (151a, 151b, 151c, 151d, 151m). The coil 40, the insulating films 145, 146, and the elastic member 151 disposed above and below the coil 40 are the same as those in the second embodiment described above, so a description thereof will be omitted.

In the third embodiment, the base 410 includes a core 420 and a bottom plate 411.

Core 420 is a magnetic material. Core 420 is made of iron, for example. The core 420 has, for example, a cylindrical shape as a whole. The core 420 has a groove 428 recessed downward from the top surface. As a result, a center convex portion 421 and an outer convex portion 425 that protrude upward when viewed from the groove portion 428 are provided. That is, the center convex portion 421 and the outer convex portion 425 are composed of one member.

The coil 40 is placed inside the groove 428 along with the insulating films 145 and 146. In the vibration generator 401, the center convex portion 421 and the outer convex portion 425 play the same role as the center convex portion 120 and the outer convex portion 125 in the second embodiment. That is, as a current flows through the coil 40, the core 420 is excited, and the upper part of the center convex part 421 and the upper part of the outer convex part 425 each become magnetic poles.

The bottom plate 411 is, for example, a plate-like member that is roughly square in plan view. The portion where the core 420 is placed is a recess 414 recessed from the peripheral portion. Core 420 is placed in recess 414 . Furthermore, a protrusion 419 is formed at the front of the bottom plate 411, on which a terminal (not shown) is arranged. For example, a through hole or notch (not shown) that penetrates between the bottom surface or the side surface of the groove 428 of the core 420 and the outer surface of the core 420 is provided. The conductive wire of the coil 40 is guided to the protrusion 419 through the section.

The bottom plate 411 may be made of a magnetic material such as iron, or may be made of another type of member such as resin. By forming the bottom plate 411 with a magnetic material, the magnetic efficiency of the magnetic circuit is improved, and the amplitude of the vibration generated by the vibration generator 1 can be increased. Moreover, the bottom plate 411 may be, for example, a circuit board or the like. The bottom plate 411 does not necessarily need to be provided with the recess 414 or the protrusion 419.

The elastic member 151 is arranged on the upper surface of the center convex portion 421 and the upper surface of the outer convex portion 425. A disk-shaped plate 430 is arranged on the elastic member 151. As a result, a magnetic circuit is configured by the plate 430 and the core 420 having the center convex portion 421 and the outer convex portion 425. The vertical thickness of the core 420 in the portion where the groove portion 428 is provided is ensured to be relatively large. Therefore, saturation of magnetic flux is less likely to occur in the magnetic circuit.

Note that a rod-shaped support portion 461 is provided at a corner of the bottom plate 411 so that the vertical direction is the longitudinal direction. Furthermore, a protrusion 462 that protrudes upward is provided on the upper surface of the plate 430. An annular rubber member 465 is placed between the support portion 461 and the protrusion portion 462 . This forms a holding structure 460 that holds the plate 430 relative to the base 410. The holding structure 460 is provided, for example, at the front right, rear right, front left, and rear left of the vibration generator 401, respectively. This prevents the plate 430 from falling off, and allows the vibration generator 401 to be used in various applications and postures.

Also in the third embodiment, a magnetic circuit is configured by a plate 430 and a core 420 having a center convex portion 421 and an outer convex portion 425. Therefore, the vibration generator 401 can function similarly to the first embodiment described above. The vibration generator 401 in the third embodiment can be used in various electronic devices in the same way as described in the first embodiment.

[Fourth embodiment]

The basic configuration of the vibration generator in the fourth embodiment is the same as that in the first embodiment, so the description here will not be repeated. Components that are substantially similar in shape or function to those described in the first embodiment may be designated by the same reference numerals, and a description thereof may be omitted.

FIG. 26 is a sectional view of a vibration generator 601 according to the fourth embodiment.

As shown in FIG. 26, the vibration generator 601 includes a base 10, a plate 630, a coil 40, and elastic members 51 (51a, 51b). As shown in FIGS. 5 and 6, a plurality of elastic members 51 are arranged on the flange portion 15 in a circumferential direction. A protrusion 635 is provided on the surface of the plate 630 facing the base 10. The protrusion 635 is arranged to face the protrusion 620 of the base 10. Note that the height of the convex portion 620 in the vertical direction is reduced by the amount that the protrusion portion 635 protrudes downward.

Also in the fourth embodiment, a magnetic circuit is configured by the protruding portion 635 and the outer peripheral portion of the plate 630, the convex portion 620, the bottom portion 14a, and the flange portion 15 of the base 10. Therefore, the vibration generator 601 can function similarly to the first embodiment described above. The protrusion 635 of the plate 630 also serves as a weight. That is, the plate 630 is provided with a protrusion 635 as a weight, and the plate 630 is relatively heavy, so that a larger vibration force can be generated.

Note that the weight may be placed on a surface other than the bottom surface of the plate 630. Further, a weight configured as a separate member from the plate 630 may be attached to the plate 630.

The upper surface of the coil 40 shown in FIG. 26 is at the same height as the upper surface of the base portion 15. By increasing the thickness of the coil 40 in this way, the magnetic attraction force can be increased. Note that the present invention is not limited to this, and the upper surface of the coil 40 may be at the same height as the upper surface of the convex portion 620.

[Fifth embodiment]

The basic configuration of the vibration generator in the fifth embodiment is the same as that in the first embodiment, so the description here will not be repeated. Components that are substantially similar in shape or function to those described in the first embodiment may be designated by the same reference numerals, and a description thereof may be omitted.

FIG. 27 is a sectional view of a vibration generator 701 according to the fourth embodiment.

As shown in FIG. 27, the vibration generator 701 includes a base 710, a plate 730, a coil 40, and elastic members 751 (751a, 751b).

The plate 730 has a structure in which an outer peripheral end 732 thereof is bent. That is, the outer peripheral end portion 732 is bent from the top surface portion 731 toward the coil 40. The outer peripheral end portion 732 is bent downward from the top surface portion 731, which is a horizontal portion.

In this embodiment, the outer peripheral end 732 of the plate 730 is located inside the outer peripheral end of the base 710. Specifically, the outer peripheral end 732 is located inside the outer peripheral end of the recess 14 of the base 710, that is, the side wall 14b. The plate 730 is attached to the base 710 side so that the outer peripheral end 732 fits into the recess 14 of the base 710. The outer peripheral end portion 732 is inserted between the outer peripheral side surface of the coil 40 and the side wall portion 14b of the base 710. An elastic member 751 is arranged between the lower end of the outer peripheral end 732 and the upper surface of the bottom 14 a of the recess 14 of the base 710 . Elastic member 751 supports plate 730 with respect to base 710 similarly to elastic member 51 in the first embodiment.

In the fifth embodiment, the plate 730 and the base 710 constitute a magnetic circuit. Therefore, the vibration generator 701 can function similarly to the first embodiment. Since the outer peripheral end 732 of the plate 730 is close to the bottom 14a and the side wall 14b of the base 710, magnetic flux leakage between the plate 730 and the base 710 is reduced (magnetic resistance is reduced). Therefore, the efficiency of the vibration generator 701 can be improved.

[Sixth embodiment]

FIG. 28 is a perspective view showing a vibration generator 801 according to the sixth embodiment. FIG. 29 is a diagram illustrating the structure of a vibration generator 801 according to the sixth embodiment.

Referring to FIGS. 28 and 29, vibration generator 801 has a rectangular parallelepiped shape as a whole. The vibration generator 801 includes a base 810, a plate 830, a coil 840, and elastic members 851 (851a, 851b).

The base 810 has a flange portion 815 in which holes 11 are formed on both left and right sides, and a recessed portion 814 recessed downward in the center portion between the two flange portions 815. The recess 814 has a rectangular shape that is longer in the left-right direction than in the front-back direction. A core 820 is placed in the recess 814 . A coil 840 is arranged around the core 820. The core 820 and the coil 840 are formed, for example, in an oval shape (including a shape formed by connecting two semicircular arcs with two line segments) that is long in the left-right direction, in accordance with the shape of the recess 814.

The plate 830 has a top surface portion 831 which is a horizontal portion, and two bent portions 832 which are a right end portion and a left end portion and are bent in a direction from the top surface portion 831 toward the coil 840. The bent portion 832 is located inside the outer peripheral end of the base 810. Specifically, the bent portion 832 is located inside the side wall portion 814a of the recessed portion 814 of the base 810. The plate 830 is attached to the base 810 side such that the lower end of the bent portion 832 fits into the recess 814 of the base 810. A lower end portion of the bent portion 832 is inserted between the outer peripheral side surface of the coil 840 and the side wall portion 814b of the base 810. An elastic member 851 is disposed between the lower end of the bent portion 832 and the upper surface of the recess 814 of the base 810. Elastic member 851 supports plate 830 with respect to base 810 similarly to elastic member 51 in the first embodiment.

In the sixth embodiment, the plate 830 and the base 810 constitute a magnetic circuit. Therefore, the vibration generator 801 can function similarly to the first embodiment. Since the bent portion 832 of the plate 830 is close to the upper surface of the recessed portion 814 of the base 810 and faces the side wall portion 814b, magnetic flux leakage between the plate 830 and the base 810 is reduced (magnetic resistance is reduced). Therefore, the efficiency of the vibration generator 801 can be improved.

Members such as the base 810 and plate 830 of the vibration generator 801 can be easily manufactured by linear bending or the like.

FIG. 30 is a perspective view showing a vibration generator 901 according to a modified example of the sixth embodiment. FIG. 31 is a diagram illustrating the structure of a vibration generator 901 according to a modified example of the sixth embodiment.

Referring to FIGS. 30 and 31, vibration generator 901 has basically the same structure as vibration generator 801 according to the sixth embodiment. In the vibration generator 901, a flat plate 930 is used instead of the plate 830. In place of the elastic member 851, elastic members 951 (951a, 951b) are arranged on the upper surface of the flange portion 815 of the base 810. The right side and left side of the plate 930 face the flange portion 815. The elastic member 951 is placed between the right side and left side of the plate 930 and the flange portion 815.

In the vibration generator 901, the flange portion 815 of the base 810 serves as a magnetic pole portion, and the plate 930 and the base 810 constitute a magnetic circuit. Therefore, like the vibration generator 801, the vibration generator 901 can function. Since the left and right sides of the plate 930 face the flange portion 815, magnetic flux leakage between the plate 930 and the base 810 is reduced (magnetic resistance is reduced). Therefore, the efficiency of the vibration generator 901 can be improved.

[others]

The vibration generator may be constructed by appropriately combining the individual features of the above-described embodiments and their modifications. For example, the external shape of the vibration generator 1 shown in FIG. 18 may be a disk shape as shown in FIG. 4, or a rectangular parallelepiped shape as shown in FIG. 28, which will be described later. Further, the vibration generator 1 shown in FIG. 18 may be changed as appropriate from the second embodiment to any of the vibration generators 101, 201, 401, 601, 701, 801, and 901 of the sixth embodiment. I don't mind.

Other members include known members such as adhesives, the aforementioned elastic members, and resin members.

The vibration generator is not limited to being thin or small as exemplified above. A large-sized vibration generator having the same basic configuration may be constructed.

The vibration generator is not limited to the above-mentioned types of electronic equipment, but can be used in various types of electronic equipment. For example, it is used in personal computers and their peripheral devices, household electronic appliances such as televisions, refrigerators, and washing machines, electronic devices such as remote controllers for operating them, electronic devices used in transportation equipment, buildings, etc. The vibration generator can be used in various electronic devices, such as electronic devices that use electronic devices.

The above embodiments should be considered to be illustrative in all respects and not restrictive. The scope of the present invention is indicated by the claims rather than the above description, and it is intended that all changes within the meaning and range equivalent to the claims are included.

1,101,201,401,601,701,801,901 Vibration generator 10,110,210,410,710,810 Base 14,814 Recess 14a Bottom 14b, 814b Side wall 15,815 Flange 20,820 Convex Part 30,630,730,830,930 Plate 40,840 Coil 51,50A,51A,50B,51B,50C,51C,51D,50E,51E,50F,151,751,851,951 Elastic member 55E Projection 56F Projection Part 116 Coil arrangement part 120,421 Center convex part 120a Recess 125,425 Outer convex part 126 Recess 145,146 Insulating film (resin film)
151m Center elastic member 228 Spacer 411 Bottom plate 420 Core 635 Projection 732 Outer peripheral end 832 Bent part 1001, 1201, 1401, 1601 Electronic device 1010, 1210, 1407, 1610 Housing 1020, 1420, 1620 Contact member 1 040 Force sensor 1205 Elasticity Member 1640 Elastic member

According to an aspect of the present invention to achieve the above object, an electronic device includes a housing, a touch panel attached to the housing , a base, a plate displaceable with respect to the base, and a plate displaceable with respect to the base. an elastic member supporting the base, the plate, and the elastic member are arranged inside the housing, a magnetic gap is formed between the plate and the base, and the plate is connected to the touch panel .
Preferably, a coil is provided.
Preferably the coil is on the plate side with respect to the base.

Claims (6)

comprising a housing, a touch panel attached to the housing, and a vibration generator disposed inside the housing,
The vibration generator includes a base and a plate that can be displaced in a direction toward and away from the base,
an elastic member connected to the plate and the touch panel,
The base is fixed to a mounting part provided on the housing,
The electronic device, wherein the outer circumferential portion of the plate is located inside the outer circumferential portion of the base. comprising a housing, a contact member attached to the housing, and a vibration generator disposed inside the housing,
The vibration generator includes a base and a plate that can be displaced in a direction toward and away from the base,
an elastic member is connected to the plate and the contact member,
The base is fixed to a mounting part provided on the housing,
a flange portion of the base is fixed to the mounting portion;
In the electronic device, an outer peripheral portion of the plate is located inside a flange portion of the base. The electronic device according to claim 2, wherein the plate is biased against the contact member. The electronic device according to claim 2 or 3, wherein the contact member is a touch panel. The electronic device according to any one of claims 1 to 4, wherein the vibration generator includes a coil. The electronic device according to claim 5, wherein the coil is on the plate side with respect to the base.

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